ee study plan effective fall 2018 - college of engineering fall_2018.pdf · ee 210 digital logic...
TRANSCRIPT
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Electrical Engineering Program
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Curriculum Structure and Study Plan
The Bachelor of Electrical Engineering curriculum is composed of 138 Credit Hours (CRHs) divided as
follows:
I. General Education Requirements (53 CRHs)
1. Mathematics & Statistics (21 CRHs)
2. Basic Sciences (12 CRHs)
3. Humanities (20 CRHs)
II. Core Requirements (85 CRHs)
1. Electrical Engineering Courses (56 CRHs)
2. College of Engineering Courses (11 CRHs)
3. Technical Electives (18 CRHs)
4. Summer Internship (0 CRHs)
I. General Education Requirements (53 CRHs)
1. Mathematics & Statistics (21 CRHs)
Course
Code Course-Title
Credit Hours (CRHs)
Pre-Requisite
Course Code
Co-
Requisite
Course
Code
Total-
CRHs Lect. Lab Tut
MAT 101 Calculus I 3 3 0 0
MAT 112 Calculus II 3 3 0 0 MAT 101
MAT 211 Calculus III 3 3 0 0 MAT 112
MAT 212 Linear Algebra 3 3 0 0 MAT 112
MAT 213 Differential Equations 3 3 0 0 MAT 112 MAT 212
MAT 224 Numerical Methods 3 3 0 0 MAT 212
STA 212 Probability and
Statistics for Engineers 3 3 0 0
MAT 112
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2. Basic Sciences (12 CRHs)
Course
Code Course-Title
Credit Hours (CRHs) Pre-
Requisite
Course
Code
Co-
Requisite
Course
Code
Total-
CRHs Lect Lab Tut
CHM 102 Introduction to
Chemistry 3 3 0 1
CHM 102 L Introduction to
Chemistry Lab 1 0 2 0
CHEM
102
PHU 103 Mechanics and Waves
for Engineers 3 3 0 1
MAT 101
PHU 103 L Mechanics and Waves
for Engineers Lab 1 0 2 0
PHU 103
PHU 124 Electromagnetism and
Optics for Engineers 3 3 0 1 PHU 103,
MAT 101
PHU 124 L Electromagnetism and
Optics for Engineers
Lab
1 0 2 0 PHU 103,
MAT 101
PHU 124
3. Humanities (20 CRHs)
Course
Code Course-Title
Credit Hours (CRHs) Pre-
Requisite
Course
Code
Co-
Requisite
Course
Code
Total-
CRHs Lect Lab Tut
ENG 101 Freshman English I 3 3 0 0
ENG 112 Freshman English II 3 3 0 0 ENG 101
ENG 222 Technical Writing 3 3 0 0 ENG 112
PHL 101 Engineering Ethics 3 3 0 0
ISL 101 Islamic Studies I 2 2 0 0
ISL 112 Islamic Studies II 2 2 0 0 ISL 101
ARB 101 Arabic Language and
Literature I 2 2 0 0
ARB 112 Arabic Language and
Literature II 2 2 0 0
ARB 101
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II. Core Requirements (85 CRHs)
1. Electrical Engineering Core Courses (56 CRHs)
Course
Code Course-Title
Credit Hours (CRHs) Pre-
Requisite
Course
Code
Co-
Requisite
Course
Code
Total-
CRHs Lect Lab Tut
EE 207 Foundations of Electrical
Engineering 3 3 0 1 PHU 124 MAT 213
EE 207 L Foundations of Electrical
Engineering Lab 1 0 2 0 EE 207
EE 208 Electric Circuits 3 3 0 0 EE 207
EE 209 Applied Electromagnetics 3 3 0 0 EE 207,
MAT 211
EE 210 Digital Logic Systems 3 3 0 0 EE 207
EE 210 L Digital Logic Systems Lab 1 0 2 0 EE 210
EE 301 Signals and Systems 3 3 0 0 EE 208,
MAT 224
EE 302 Communications Theory 3 3 0 0 EE 301,
STA 212
EE 302 L Communications Theory Lab 1 0 2 0 EE 302
EE 303 Introduction to Electronics 3 3 0 0 EE 208
EE 303 L Introduction to Electronics Lab 1 0 2 0 EE 303
EE 304 Microelectronics 3 3 0 0 EE 303
EE 304 L Microelectronics Lab 1 0 2 0 EE 304
EE 305 Computer Networks 3 3 0 0
SE 100,
STA 212,
EE 210 or
SE 223
EE 305 L Computer Networks Lab 1 0 2 0 EE 305
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EE 306 Control and Feedback System
Design 3 3 0 0 EE 301
EE 306 L Control and Feedback System
Design Lab 1 0 2 0 EE 306
EE 307 Computer Architecture 3 3 0 0
SE 100,
EE 210 or
SE 223
EE 307 L Computer Architecture Lab 1 0 2 0 EE 307
EE 308 Electrical Energy Conversion 3 3 0 0 EE 209
EE 308 L Electrical Energy Conversion
Lab 1 0 2 0 EE 308
EE 405 Electric Power Systems 3 3 0 0 EE 308,
MAT 224
EE 413 Digital Communications 3 3 0 0 EE 302
EE 413 L Digital Communications Lab 1 0 2 0 EE 413
EE 491 Capstone Project I 2 0 4 0 EE 390
EE 492 Capstone Project II 2 0 4 0 EE 491
2. College of Engineering Courses (11 CRHs)
Course
Code Course-Title
Credit Hours (CRHs) Pre-
Requisite
Course
Code
Co-
Requisite
Course
Code
Total-
CRHs Lect Lab Tut
SE 100 Programming for Engineers 3 3 0 0
SE 100 L Programming for Engineers
Lab 1 0 2 0
SE 100
ME 201 Materials Science and
Engineering 3 3 0 0 CHM 102
ME 201 L Materials Science and
Engineering Lab 1 0 2 0 ME 201
IE 315Engineering Economy and Cost
Analysis 3 3 0 0
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3. Technical Electives (18 CRHs)
Select three courses with their labs and two courses without labs from the following list:
Course
Code Course-Title
Credit Hours (CRHs)
Pre-Requisite
Course Code
Co-
Requisite
Course
Code
Total-
CRHs Lect Lab Tut
EE 401 Special Topics in
Electrical Engineering 3 3 0 0 EE 390
EE 401 L Special Topics in
Electrical Eng. Lab 3 0 2 0 EE 401
EE 402 Introduction to Wireless
Networks 3 3 0 0 EE 305
EE 403 Wireless
Communications 3 3 0 0 EE 413
EE 403 L Wireless
Communications Lab 1 0 2 0 EE 403
EE 404 Data Engineering in
Electrical Systems 3 3 0 0 EE 301
EE 404 L Data Engineering in
Electrical Systems Lab 1 0 2 0 EE 404
EE 406 Digital Electronics 3 3 0 0 EE 304
EE 406 L Digital Electronics Lab 1 0 2 0 EE 406
EE 408 Communication
Electronics 3 3 0 0 EE 304
EE 412 Nanoelectronics 3 3 0 0 EE 304
EE 412 L Nanoelectronics Lab 1 0 2 0 EE 412
EE 417 Digital Signal Processing 3 3 0 0 EE 301
EE 417 L Digital Signal Processing
Lab 1 0 2 0 EE 417
EE 418 Digital Image Processing 3 3 0 0 EE 301
EE 418 L Digital Image Processing
Lab 1 0 2 0 EE 418
EE 420 Power Electronics 3 3 0 0 EE 304
EE 420 L Power Electronics Lab 1 0 2 0 EE 420
EE 422 Antennas and Wave
Propagation 3 3 0 0 EE 209
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EE 423 Optical Fiber
Communication Systems
3 3 0 0 EE 422
EE 424 Optoelectronics 3 3 0 0 EE 304
EE 424 L Optoelectronics Lab 1 0 2 0 EE 424
EE 425 Microwave Engineering 3 0 0 0 EE 422
EE 426 Renewable Energy 3 3 0 0 EE 405
EE 426 L Renewable Energy Lab 1 0 2 0 EE 426
EE 427 Digital Control 3 3 0 0 EE 306
EE 428 Modern Control Theory 3 3 0 0 EE 306
EE 435 Undergraduate Research
in Electrical Engineering 3 0 6 0
Department
Chair approval,
a min. 3.0 GPA,
& a signed
research
contract.
4. Summer Internship (0 CRHs)
Course
Code Course-Title Credit Hours (CRHs)
Pre-Requisite
Course Code
Co-
Requisite
Course
Code
EE 390 Electrical Engineering
Summer Internship 0
EE 302, EE 304,
EE 306, EE 308
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Typical Study Plan-Electrical Engineering Program
4-Year Curriculum: 138 Credit Hours Total
Each course below follows the following format:
Course code, Course Title, and Course Credit Hours (Lecture contact hours – Lab contact hours –
Tutorial contact hours)
1st Year
Fal
l
Course Code Course-Title CRHs
SE 100 Programming for Engineers 3 (3-0-0)
SE 100 L Programming for Engineers Lab 1 (0-2-0)
CHM 102 Introduction to Chemistry 3 (3-0-1)
CHM 102 L Introduction to Chemistry Lab 1 (0-2-0)
MAT 101 Calculus I 3 (3-0-0)
PHU 103 Mechanics and Waves for Engineers 3 (3-0-1)
PHU 103 L Mechanics and Waves for Engineers Lab 1 (0-2-0)
ENG 101 Freshman English I 3 (3-0-0)
Total 18
Sp
rin
g
Course Code Course-Title CRHs
ME 201 Materials Science and Engineering 3 (3-0-1)
ME 201 L Materials Science and Engineering Lab 1 (0-2-0)
MAT 112 Calculus II 3 (3-0-0)
PHU 124 Electromagnetism and Optics for Engineers 3 (3-0-1)
PHU 124 L Electromagnetism and Optics for Engineers Lab 1 (0-2-0)
PHL 101A Engineering Ethics 3 (3-0-0)
ENG 112 Freshman English II 3 (3-0-0)
Total 17
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2nd
Year
Fal
l
Course Code Course-Title CRHs
EE 207 Foundations of Electrical Engineering 3 (3-0-1)
EE 207 L Foundations of Electrical Engineering Lab 1 (0-2-0)
MAT 211 Calculus III 3 (3-0-0)
MAT 212 Linear Algebra 3 (3-0-0)
MAT 213 Differential Equations 3 (3-0-0)
ISL 101 Islamic Studies I 2 (2-0-0)
ENG 222 Technical Writing 3 (3-0-0)
Total 18
Sp
rin
g
Course Code Course-Title CRHs
EE 208 Electric Circuits 3 (3-0-0)
EE 209 Applied Electromagnetics 3 (3-0-0)
EE 210 Digital Logic Systems 3 (3-0-0)
EE 210 L Digital Logic Systems Lab 1 (0-2-0)
MAT 224 Numerical Methods 3 (3-0-0)
STA 212 Probability and Statistics for Engineers 3 (3-0-0)
Total 16
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3rd
Year
Fal
l
Course Code Course-Title CRHs
EE 301 Signals and Systems 3 (3-0-0)
EE 303 Introduction to Electronics 3 (3-0-0)
EE 303 L Introduction to Electronics Lab 1 (0-2-0)
EE 305 Computer Networks 3 (3-0-0)
EE 305 L Computer Networks Lab 1 (0-2-0)
EE 307 Computer Architecture 3 (3-0-0)
EE 307 L Computer Architecture Lab 1 (0-2-0)
ARB 101 Arabic Language and Literature I 2 (2-0-0)
Total 17
Sp
rin
g
Course Code Course-Title CRHs
EE 302 Communications Theory 3 (3-0-0)
EE 302 L Communications Theory Lab 1 (0-2-0)
EE 304 Microelectronics 3 (3-0-0)
EE 304 L Microelectronics Lab 1 (0-2-0)
EE 306 Control and Feedback System Design 3 (3-0-0)
EE 306 L Control and Feedback System Design Lab 1 (0-2-0)
EE 308 Electrical Energy Conversion 3 (3-0-0)
EE 308 L Electrical Energy Conversion Lab 1 (0-2-0)
IE 315 Engineering Economy and Cost Analysis 3 (3-0-0)
Total 19
Su
mm
er Course Code Course-Title CRHs
EE 390 Electrical Engineering Summer Internship 0
Total 0
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4th
Year
Fal
l
Course Code Course-Title CRHs
EE 405 Electric Power Systems 3 (3-0-0)
EE 413 Digital Communications 3 (3-0-0)
EE 413 L Digital Communications Lab 1 (0-2-0)
EE 491 Capstone Project I 2 (0-4-0)
EE 4** Technical Elective 3 (3-0-0)
EE 4** Technical Elective 3 (3-0-0)
EE 4** L Technical Elective Lab 1 (0-2-0)
ISL 112 Islamic Studies II 2 (2-0-0)
Total 18
Sp
rin
g
Course Code Course-Title CRHs
EE 492 Capstone Project II 2 (0-4-0)
EE 4** Technical Elective 3 (3-0-0)
EE 4** Technical Elective 3 (3-0-0)
EE 4** L Technical Elective Lab 1 (0-2-0)
EE 4** Technical Elective 3 (3-0-0)
EE 4** L Technical Elective Lab 1 (0-2-0)
ARB 112 Arabic Language and Literature II 2 (2-0-0)
Total 15
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Course Descriptions
In this section we give the course descriptions of Electrical Engineering courses of the program. All
specifications for all courses of the program are listed in Appendix C.
Each course below follows the following format: Course Code Course Title Course Credit Hours (Lecture contact hours – Lab contact hours – Tutorial contact hours)
Course Description
Pre-requisites
Co-requisites
Core Courses
EE 207: Foundation of Electrical Engineering 3 (3-0-1)
The course teaches fundamental concepts of electrical circuits, students will be familiarized with the essential
principles of electrical circuit analysis composition of components into systems and networks, and
understanding the trade-offs and limits imposed by energy and noise. Students learn to apply the concepts
during laboratory design.
Pre-requisites: PHU 124
Co-requisites: MAT 213
EE 207 L: Foundation of Electrical Engineering Lab 1 (0-2-0)
Laboratory experiments dealing with Foundation of Electrical Engineering.
Pre-requisites: None
Co-requisites: EE 207
EE 208: Electric Circuits 3 (3-0-0)
The course teaches the design and analysis of interconnected networks of lumped circuit elements.
Pre-requisites: EE 207
Co-requisites: None
EE 209: Applied Electromagnetics 3 (3-0-0)
The course teaches the application of electromagnetic principles to classical and modern devices. The concepts
of work and energy and electromagnetic fields are addressed.
Pre-requisites: EE 207, MAT 211
Co-requisites: None.
EE 210: Digital Logic Systems 3 (3-0-0)
The course teaches theoretical foundations and concepts of digital systems and applies these concepts with
design problems and projects. Students are exposed to the design and engineering of digital computers and
subsystems.
Pre-requisites: EE 207
Co-requisites: None
EE 210 L: Digital Logic Systems Lab 1 (0-2-0)
Laboratory experiments dealing with Digital Logic Systems.
Pre-requisites: None.
Co-requisites: EE 210
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EE 301: Signals and Systems 3 (3-0-0)
The course teaches fundamental concepts of signals and systems analysis, with applications drawn from
filtering, audio and image processing, communications, and automatic control. The objective of the course is to
allow students to develop a thorough understanding of time-domain and frequency domain approaches to the
analysis of continuous and discrete systems. To provide students with necessary tools and techniques to analyze
electrical networks and systems.
Pre-requisites: EE 208, MAT 224
Co-requisites: None
EE 302: Communications Theory 3 (3-0-0)
The course teaches communication systems and information theory. Topics covered include the classification of
signals and systems, Fourier series and transform applications, power spectra and spectral density, band-limited
signals and noise, sampling theory and digital transmission, modulation techniques and pulse code modulation.
Pre-requisites: EE 301, STA 212
Co-requisites: None
EE 302 L: Communications Theory Lab 1 (0-2-0)
Laboratory experiments dealing with Communications Theory.
Pre-requisites: None
Co-requisites: EE 302
EE 303: Introduction to Electronics 3 (3-0-0)
The course teaches the fundamentals of electronic circuits, including diode characteristics and diode circuits,
transistors and applications, switches and MOS transistors, amplifiers, energy storage elements, digital circuits
and applications. Design and laboratory exercises are also significant components of the course.
Pre-requisites: EE 208
Co-requisites: None
EE 303 L: Introduction to Electronics Lab 1 (0-2-0)
Laboratory experiments dealing with Introduction to Electronics.
Pre-requisites: None.
Co-requisites: EE 303
EE 304: Microelectronics 3 (3-0-0)
This course teaches analog circuit analysis and design, including an introduction to the tools and methods
necessary for the creative design of practical circuits using active devices.
Pre-requisites: EE 303
Co-requisites: None
EE 304 L: Microelectronics Lab 1 (0-2-0)
Laboratory experiments dealing with Microelectronics.
Pre-requisites: None.
Co-requisites: EE 304
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EE 305: Computer Networks 3 (3-0-0)
The course teaches the fundamental concepts of communication networks, and is concerned specifically with
network architectures and protocols. The objective of the course is to allow students to develop a thorough
understanding of the architectures of networks and the basic principles that allow the transmission of data over
networks.
Pre-requisites: SE 100, STA 212, EE 210 (or SE 223)
Co-requisites: None
EE 305 L: Computer Networks Lab 1 (0-2-0)
Laboratory experiments dealing with Computer Networks.
Pre-requisites: None
Co-requisites: EE 305
EE 306: Control and Feedback System Design 3 (3-0-0)
The course teaches the analysis and synthesis of continuous and sampled-data linear feedback control systems,
and its application to a variety of physical systems
Pre-requisites: EE 301
Co-requisites: None
EE 306 L: Control and Feedback System Design Lab 1 (0-2-0)
Laboratory experiments dealing with Control and Feedback System Design.
Pre-requisites: None
Co-requisites: EE 306
EE 307: Computer Architecture 3 (3-0-0)
The course introduces the architecture of digital systems, with an emphasis on the structural principles common
to a wide range of computer technologies. Multilevel implementation strategies, the definition of new primitives
(e.g., gates, instructions, procedures, and processes) and their mechanization using lower-level elements, the
organization and operation of digital computers and the hardware/software interface are addressed.
Pre-requisites: SE 100, EE 210 (or SE 223)
Co-requisites: None
EE 307 L: Computer Architecture Lab 1 (0-2-0)
Laboratory experiments dealing with Computer Architecture.
Pre-requisites: None
Co-requisites: EE 307
EE 308: Electrical Energy Conversion 4 (3-2-0)
The course teaches the basic concepts of electrical machines and power semiconductor converters and their
application within modern power systems.
Pre-requisites: EE 209
Co-requisites: None
EE 308 L: Electrical Energy Conversion Lab 1 (0-2-0)
Laboratory experiments dealing with Electrical Energy Conversion.
Pre-requisites: None
Co-requisites: EE 308
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EE405: Electric Power Systems 3 (3-0-0)
The course teaches the components, analysis, and modeling of large scale electric power systems. This includes
the review of single and three phase circuit variables and parameters and the per unit system. The components
of the system are studied including the transformers and the transmission line parameters. In addition, the
operation in terms of modeling and analysis of electric power systems is studied in steady state and transient
state, with a particular focus on power flow solution methods. Case studies are introduced to prepare for more
advanced topics. A project accompanies the course to introduce practical aspects of measurements and
operation, with simulations addressing large scale problems.
Pre-requisites: EE308, MAT 224
Co-requisites: None
EE 413: Digital Communications 3 (3-0-0)
The course teaches the principles of digital communication systems. Topics include sampling, quantization and
encoding of analog signals, pulse code modulation (PCM), delta modulation (DM), noise analysis in PCM and
DM systems, base-band digital systems (matched filter, probability of error, inter-symbol interference,
equalization, distortionless transmission, and M-ary transmission), line codes and their power spectra, pass-band
digital systems (ASK, FSK PSK, DPSK, and M-ary), bandwidth and power requirements of modulation
schemes, coherent and non-coherent detection, error rate analysis, and introduction to information theory.
Pre-requisites: EE 302
Co-requisites: None
EE 413 L: Digital Communications Lab 1 (0-2-0)
Laboratory experiments dealing with Digital Communications.
Pre-requisites: None
Co-requisites: EE 413
EE 490: Capstone Project I 2 (0-4-0)
Students work in teams as professional engineering consultants on an independent engineering project under the
supervision of a project advisor. The design process is emphasized, encompassing project definition, feasibility
analysis, evaluation of alternative designs, and design computations. For each project, the scope of work is
developed and negotiated between client and student consultants. The scope of work may also include
fabrication, device testing, and field-testing. Projects are arranged by the students with approval of the
instructor. The design and methodology are emphasized in part 1. Progress reports and an end of term report are
submitted to the project advisor with an oral presentation of the design and methodology of the project.
Pre-requisites: EE 390
Co-requisites: None
EE 492: Capstone Project II 2 (0-4-0)
The students work on the implementation and validation of the designs developed in part 1. A demonstration is
presented and a final written report is submitted to the project advisor. Oral presentations of reports are made
before the faculty and students. A student who selects a project suggested by the industry has the opportunity of
working with an industry sponsor.
Pre-requisites: EE 491
Co-requisites: None
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Elective Courses
EE401 Special Topics in Electrical Engineering 3 (3-0-0)
This course provides instruction and experience in timely topics related to Electrical Engineering major.
Pre-requisites: EE 390
Co-requisites: None
EE401 Special Topics in Electrical Engineering Lab 1 (0-2-0)
Laboratory experiments dealing with the special topics course. This will be offered if the special topics course
has an applied side and is scheduled to be offered with a lab.
Pre-requisites: None
Co-requisites: EE 401
EE 402: Introduction to Wireless Networks 3 (3-0-0)
The course surveys the various types of wireless communications, the protocols involved and the design issues
that nature and engineering impose upon the telecommunications engineer. Specifically, the course covers
wireless network architectures including cellular networks, local area networks, multi-hop wireless networks
such as ad hoc networks, mesh networks, and sensor networks; capacity of wireless networks; medium access
control, routing protocols, and transport protocols for wireless networks; mechanisms to improve performance
and security in wireless networks; energy-efficient protocols for sensor networks.
Pre-requisites: EE 305
Co-requisites: None.
EE 403: Wireless Communications 3 (3-0-0)
The course teaches wireless communications for voice, data, and multimedia. Topics include wireless systems
and standards, characteristics of the wireless channel, including path loss for different environments, random
log-normal shadowing due to signal attenuation, and the flat and frequency-selective properties of multipath
fading.
Pre-requisites: EE 413
Co-requisites: None
EE 403 L: Wireless Communications Lab 1 (0-2-0)
Laboratory experiments dealing with Wireless Communications.
Pre-requisites: None
Co-requisites: EE 403
EE 404: Data Engineering in Electrical Systems 3 (3-0-0)
The course introduces students to data engineering and science (DES) techniques, with a focus on application to
substantive (i.e. "applied") engineering problems. Students will gain experience in identifying which problems
can be tackled by DES methods, and learn to identify which specific DES methods are applicable to a problem
at hand.
Pre-requisites: EE 301
Co-requisites: None
EE 404 L: Data Engineering in Electrical Systems Lab 1 (0-2-0)
Laboratory experiments dealing with Data Engineering in Electrical Systems.
Pre-requisites: None
Co-requisites: EE 404
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EE 406: Digital Electronics 3 (3-0-0)
This course aims to familiarize students with the basic concepts and mechanisms of operation and design of
digital electronic circuits, both discrete and integrated. Topics covered include an overview of MOS and BJT
types, structures and operation, digital logic inverters (voltage transfer characteristic, digital integrated circuit
technologies and logic-circuit families), CMOS inverters (dynamic operation of the CMOS inverter, inverter
sizing, power dissipation), logic-gate circuits (NOR, NAND, XOR), propagation delay analysis, pseudo-NMOS
logic circuits, gate circuits, pass-transistor logic circuits (NMOS transistors as switches, CMOS transmission
gates as switches), dynamic MOS logic circuits (Emitter-coupled logic (ECL) and families), BiCMOS inverters
and logic gates, latches, flip-flop circuits, multivibrators, and an overview of memory circuits types and
architectures, and A/D and D/A converters.
Pre-requisites: EE 304
Co-requisites: None
EE 406 L: Digital Electronics Lab 1 (0-2-0)
Laboratory experiments dealing with Digital Electronics.
Pre-requisites: None
Co-requisites: EE 406
EE 408: Communication Electronics 3 (3-0-0)
This course is designed for senior-level undergraduate students in Electrical Engineering. It builds upon
perquisite courses on signal and systems, communications, control systems, and electronics to further enhance
the understanding of communication circuits operation and physical implementation. The course focuses on the
field of communication electronics at levels from block diagram to circuit analysis for physical implementation.
It aims to cover topics as radio frequency amplifiers, oscillators, signal spectra, noise, modulation and AM
systems, transmitter and receiver circuits, sideband systems, frequency and phase modulation, phase-locked
loops, and pulse and digital modulation.
Pre-requisites: EE 304
Co-requisites: None
EE 412: Nanoelectronics 3 (3-0-0)
The course teaches an introduction to the electronic properties of molecules, carbon nanotubes, crystals and
other nanodevices.
Pre-requisites: EE 304
Co-requisites: None
EE 412 L: Nanoelectronics Lab 1 (0-2-0)
Laboratory experiments dealing with Nanoelectronics.
Pre-requisites: None
Co-requisites: EE 412
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EE 417: Digital Signal Processing 3 (3-0-0)
This course presents an introduction to the techniques and algorithms of digital processing for signals and
information data. It is designed for senior-level undergraduate students in electrical and computer engineering.
The theory and practice covered in this course can be applied in wide range of science fields, such as image
processing, communications, satellite systems, biomedical, power and electronic devices, and programmable
units. The proposed content covers a review of discrete-time sequences and systems, sampling of continuous-
time signals and aliasing effect, discrete Fourier transform: properties and applications; fast Fourier transform
(FFT): implementation and computations, finite impulse response (FIR) filters design and analysis: low-pass,
band pass, high pass, phase response etc., and infinite impulse response (IIR) filters design methods and
cascaded structures. The course involves extensive software and programming experience to enrich the
understanding of the covered material.
Pre-requisites: EE 301
Co-requisites: None
EE 417 L: Digital Signal Processing Lab 1 (0-2-0)
Laboratory experiments dealing with Digital Signal Processing.
Pre-requisites: None
Co-requisites: EE 417
EE 418: Digital Image Processing 3 (3-0-0)
The course teaches an introduction to image processing and its applications, including the fundamental concepts
of visual perception and image acquisition, the basic techniques of image manipulation, segmentation and
coding, and a preliminary understanding of pattern recognition and computer vision.
Pre-requisites: EE 301
Co-requisites: None
EE 418 L: Digital Image Processing Lab 1 (0-2-0)
Laboratory experiments dealing with Digital Image Processing.
Pre-requisites: None
Co-requisites: EE 418
EE 420: Power Electronics 3 (3-0-0)
The course teaches the principles of designing power electronic circuits. Power electronics design has
applications in several fields from motor drives to consumer electronics to electric power transmission over
HVDC lines. Therefore, the course reviews the fundamentals before covering generic power electronic circuit
topologies. This entails a review of the switching devices, e.g., diodes, thyristors, BJTs, and the review of the
fundamentals of electric circuit design and magnetism. Building on the fundamentals, the course covers AC to
DC, DC to DC, DC to AC, and AC to AC electric power conversion topologies. The lab component is
simultaneously administered to offer a practical perspective including the selection of components vis-à-vis the
application, the instrumentation. In addition, the lab goes over the prototyping and testing aspects of power
electronic circuit design.
Pre-requisites: EE 304
Co-requisites: None
Electrical Engineering Program
(
(
(
233"45$#"'(6*77(./08-(!"#$%"&'()*+(,-(./01
18
EE 420 L: Power Electronics Lab 1 (0-2-0)
Laboratory experiments dealing with Power Electronics.
Pre-requisites: None
Co-requisites: EE 420
EE 422: Antennas and Wave Propagation 3 (3-0-0)
This course introduces the characteristics of electromagnetic waves and their behavior during the propagation
through different media. The wave equation is derived using the Maxwell’s equations for time varying fields.
The electromagnetic wave propagation in different media as well as their reflection at normal and oblique angle
of incidence is discussed. The concept of transmission line theory and its parameters, smith chart and its
application are introduced. Waveguide and TM & TE modes are discussed. In addition the course includes
Antenna characteristics, antenna types such as dipole, loop and antenna array.
Pre-requisites: EE 209
Co-requisites: None
EE 423: Optical Fiber Communication Systems 3 (3-0-0)
The course teaches the introduction to the optical fiber communications. Topics discusses dielectric slab
waveguide, step-index and graded-index optical fibers, single mode and multimode fiber, attenuation and
dispersion, light sources (LED and Laser diode), optical modulation and detection, noise modeling in optical
receivers, and error rate analysis.
Pre-requisites: EE 422
Co-requisites: None
EE 424: Optoelectronics 3 (3-0-0)
The course teaches semiconductor light sources, such as different types of LEDs, Lasers (both gas and solid
states), modulation techniques, photodetectors, PIN diode, avalanche Photo Diode (APD), the basics of optical
waveguides and the principles of fiber optics
Pre-requisites: EE 304
Co-requisites: None
EE 424 L: Optoelectronics Lab 1 (0-2-0)
Laboratory experiments dealing with Optoelectronics.
Pre-requisites: None
Co-requisites: EE 424
EE 425: Microwave Engineering 3 (3-0-0)
The course teaches the fundamentals of Microwave Engineering. Topics include a review of electromagnetics
theory, and discuss transmission lines and waveguides, microwave network analysis, impedance matching,
passive microwave devices (power dividers and directional couplers), strip-line and micro-strip line circuits,
microwave filters, and introduction to ferrimagnetic materials and components.
Pre-requisites: EE 422
Co-requisites: None
Electrical Engineering Program
(
(
(
233"45$#"'(6*77(./08-(!"#$%"&'()*+(,-(./01
19
EE 426: Renewable Energy 3 (3-0-0)
This course covers fundamentals of renewable energy systems, Solar energy, Bio-energy, Wind energy, Hydro-
power, Tidal power, Wave energy and Geothermal energy. Also integration of renewable energy systems will be
covered in the course. The students will be exposed to technical aspects of mentioned topics; How to utilize
renewable energy for domestic and industrial applications; requirements and obstacles of applications; how to
integrated renewable energy systems.
Pre-requisites: EE 405
Co-requisites: None
EE 426 L: Renewable Energy Lab 1 (0-2-0)
Laboratory experiments dealing with Renewable Energy.
Pre-requisites: None
Co-requisites: EE 426
EE 427: Digital Control 3 (3-0-0)
The course discusses digital control designs and methodologies for dynamic systems. It describes classical and
state-space control methods, and applies them to selected applications. The course explores the advantages and
limitations of each method, offers an overview of feedback control systems, and proposes to cover selected
topics on multivariable and optimal control methods. The course involves Matlab experience to improve the
understanding of the covered design methods. The topics include a review of continuous control (feedback, root
locus, frequency response design, compensation, state-space design), basic digital control (digitization,
sampling, PID), discrete systems (linear difference equations, z-transform, spectrum, block diagrams), discrete
equivalents (design via numerical integration, zero-pole matching), transform techniques (root locus in z-plane,
frequency response), state-space approaches (regulator design, integral control and disturbance estimation,
controllability and observability), and an introduction to multivariable and optimal control (time-varying and
LQR steady-state optimal control, multivariable design)
Pre-requisites: EE 306
Co-requisites: None
EE 428: Modern Control Theory 3 (3-0-0)
The course covers the fundamentals of Matrix Theory including eigenvalues and eigenvectors, and the matrix
representations of the Diagonal, Jordan, Controllable, and Observable forms. The student learns to represent
systems in terms of their state variables and state diagrams, and then solve for their response in the time domain.
The focus of the course is on linear time invariant or LTI systems. Furthermore, the controllability and
observability of the LTI system is studied, before covering the design of state feedback and output feedback
control techniques. In addition, observer design is covered, with the separation principle, to construct observer-
based control systems.
Pre-requisites: EE 306
Co-requisites: None
Electrical Engineering Program
(
(
(
233"45$#"'(6*77(./08-(!"#$%"&'()*+(,-(./01
20
EE 435: Undergraduate Research in Electrical Engineering 3 (0-6-0)
Students participate in supervised research with a faculty member. Supervised research can be: 1) independent
research undertaken by the student (thesis, independent study), or 2) assistance on a faculty member’s research
project. Students must find a faculty member who is willing to supervise him/her as an assistant on an existing
project or as the author of an individual project. The student and the faculty supervisor will complete and sign a
research contract which will be turned in to the chair of the Electrical Engineering Department. Drafting the
contract will allow the student to develop ideas about what should be accomplished and what the faculty
supervisor’s expectations are. All academic requirements are at the discretion of the supervising faculty
member. Students should agree on a plan for the semester with the faculty mentor before the research begins.
The plan should include academic requirements, the basis for grading the experience, and a plan for
student/professor meetings for the semester. It is the student’s responsibility to report progress and seek
guidance when needed. Students are expected to be active and reliable participants in the research experience.
Pre-requisites: Department Chair approval, a GPA of at least 3.0/4.0, and a signed research contract.
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